MS-553 Therapy Inhibits BCR Signaling and Increases Survival Dependence on BCL-2 in BTK-Inhibitor Resistant CLL

B-cell receptor (BCR) signaling pathway inhibitors and B-cell lymphoma-2 (BCL-2) antagonist venetoclax (Ven) have transformed the treatment of chronic lymphocytic leukemia (CLL), including in high-risk patients with 17p deletion and/or TP53 mutations and complex karyotype. Despite the durable remissions observed with inhibitors of Bruton’s Tyrosine Kinase (BTKi), a significant proportion of patients develop resistance with acquired mutations in BTK and its downstream target phospholipase Cγ2 (PLCG2). Patients who progress on BTKi including ibrutinib (ibr) often receive Ven but eventually relapse, underscoring an urgent need for new treatment strategies. Protein kinase C-β (PKC-ß) is a protein downstream of BCR signaling (BTK-PLCG2) and is essential for CLL cell survival and proliferation in vivo. Here we investigate MS-553, an inhibitor of PKC-ß, with a focus of combination strategies in CLL patient samples including relapsed/refractory CLL.

We show that CLL cells in contact with stroma upregulate PKC-ßII, its immediate downstream effectors, pGSK and pERK as well as ß-catenin in CLL patients including those with mutant TP53 and 17p (n=8). Correspondingly, MS-553 (5µM, 48h) exposure reduced levels of p-PKC-ßII and its downstream effectors (p-ERK, p-GSK) in a dose dependent manner regardless of TP53 mutation in both CLL cells and those supported by NK.Tert (stromal cell line derived from bone marrow, BM, and mimics BM microenvironment). Pre-treatment (48h, 5µM MS-553) of stromal NK.Tert cells with MS-553 prevented the upregulation of PKC-ßII within adjacent CLL cells implicating the stroma as a major source of PKC-ß activation in CLL cells. We also tested whether MS-553 could inhibit PKC-ß signaling in CLL cells exposed to phorbol myristate acetate (PMA-400nM, 90 min), which simulates BCR activation. MS-553 (5µM, 48h) exposure caused downregulation of BTK effectors (pPKC-ßII, pERK, pGSK), BCL-2 family member proteins (MCL-1 and BCLxl), and ß-catenin (n=10). In parallel experiments, we used BH3 profiling to show that CLL cells’ (n=8) exposure to MS-553 in vitro developed increased dependence on BCL-2 and BCLxl for survival (Bim, Bad, XXA1_y4ek, 5-fold± 2-fold increase) in both wild type (WT) and mutant (Mut) CLL cells, suggesting a mechanistic rationale for synergy with Ven. To confirm this, CLL cells were exposed to MS-553, Ven or a combination of MS-553 and Ven. ~3-fold and 9-fold synergistic increase in the mitochondrial dysfunction (measured by cytochrome C release, 12h, 5µM MS-553, 1nM Ven) was observed in stromal supported WT and Mut CLL respectively in MS-553 versus Ven+MS-553 treated group. Similarly, ~3-fold increase was observed in WT and Mut CLL alone group and more than 10-fold increase was found in stromal supported WT and Mut group in cell death determined as percent apoptotic index (measured by annexin V-PI staining, 18h, 5µM MS-553, 1nM Ven) in MS-553 versus Ven+MS-553 group respectively. Finally, we validated our preclinical findings in CLL samples obtained from four patients on MS-553 therapy (NCT03492125, Range = cycles 0-19, MS-553 28 days/cycle). All patients showed an increase in survival dependence towards BCL-2 and BCLxl by Cycle 3-6 of MS-553 therapy. This was accompanied by downregulation of ß-catenin, pPKC-ßII, pGSK, pERK along with BCLxl and MCL-1 after Cycle 10 or later of MS-553 therapy (data summary table1). Overall, our data provides clear evidence that MS-553 inhibits BCR signaling in vitro and in patients on MS-553 therapy. It also provides a rationale for combinations with Ven as a treatment partner based on its ability to increase survival dependence on BCL-2.